Jan., 1949
KINETICSOF
OXIDATION OF 2-DEUTEROPROPANOL BY CHROMIC ACID
Co., for the sample of perfluoromethylcyclohexane, and the Office of Naval Research for financial support of this research.
Summary Liquid-liquid solubility curves have been determined for binary mixtures of perfluoromethylcyclohexane with five other liquids, giving the following results for the critical solution temperatures in OC. and the mole fractions of the second [CONTRIBUTION FROM
THE
25
components: carbon tetrachloride, 26.8', 0.70; chloroform, 50.3O, 0.74; benzene, 85.3', 0.73 ; toluene, 88.8', 0.69; chlorobenzene, 126.8', 0.69. These values agree within the usual limits of error with those calculated by aid of the equations for regular solutions and the value 6.0, previously derived by Scott for the "solubility parameter" (the square root of the energy of vaporization per cc.) of the fluorocarbon. BERKELEY,CALIF.
RECEIVED AUGUST23, 1948
GEORGE HERBERT JONES LABORATORY OF THE UNIVERSITY OF CHICAGO]
The Kinetics of the Oxidation of 2-Deuteropropanol-2 by Chromic Acid BY F. H. WESTHEIMER AND NICHOLAS NICOLAIDES The rate of the chromic acid oxidation of isopropyl alcohol to acetone has been shown to be proportional to the concentrations of isopropyl alcohol and the acid chromate ion, and proportional to the square of the concentration of hydrogen ion.' Although these kinetics fix the composition of the activated complex in the oxidation, they leave unanswered many questions concerning the mechanism. Specifically, they do not show whether the oxidative attack upon the alcohol molecule is at the secondary hydrogen atom, a t the hydroxyl hydrogen atom,2 or elsewhere. This question can be answered by studying the rate of oxidation of 2deuteropropanol-2. Both experimental and theoretical considerations show that, if the deuterium atom of 2-deuteropropanol-2 is removed in the rate-controlling step of the oxidation, the 2-deuteroalcohol will be oxidized much less rapidly than the corresponding hydrogen compound. On the other hand, if the rate determining step does not involve the removal of this deuterium atom, the oxidation rates for the hydrogen and deuterium compounds should be almost if not exactly identical. This test for the direct removal of a hydrogen atom depends upon thC fact that C-H and C-D bonds differ in their zero-point energies. The method is completely general3; it has been strikingly applied by Reitz4 in a study of the rate of enolization of acetone and of the deuteroacetones. In the present work, it has been found that 2-deuteropropanol-2 is oxidized by chromic acid only about one-sixth as fast as is ordinary isopropyl alcohol; it follows unambiguously that the secondary hydrogen atom is removed during the rate controlling step of the reaction. (1) Westheimer and Novick, J . Chem. Phys., 11, 506 (1943). (2) Mosher, Abstracts, September, 1947, meeting of the American Chemical Society. Mosher and Whitmore, THISJ O U R N A L 70, 2614 (1948). (3) Urey and Teal, RED'. M o d . P h y s . , 7, 34 (1935); c f . Taylor and Eyring, Proc. A m . Phil. Soc., 11, 255 (1933). (4) Reitz, Z. physik. Chem., 8179, 119 (1937); i b i d . , A184, 429 11939): cf., however, Wynne-Jones, J . Chem. Phys., 2, 381 (1934): Reitz, Z. physik. Chcm., 8176, 363 (1936): and Maron and LaMer. THISJOURNAL, 60, 2588 (1938).
Experimental Deuterium.-The deuterium for these experiments was made by vaporizing 12.1 g. of Norwegian heavy water (Norsk Hydro Elektrish Kvaelstofaktieselskat 99.73% D?O; deo, 1.10516) over Grignard magnesium heated electrically to 490 * 25" in a heavy-walled combustion tube.6 The resulting deuterium gas was passed through alkaline permanganate and stored over a saturated solution of sodium sulfate. 2-Deuteropropanol-2.-2-Deuteropropanol-2 was made by the catalytic deuteration of acetone according t o the directions of Anderson and MacNaughtonP Eighty-six grams of acetone (J. T. Baker reagent grade, previously dried with potassium carbonate and distilled) was deuterated with 10.8 liters of deuterium gas, by means of 1.62 g. of Adams catalyst promoted with a few crystals of ferrous chloride. The deuteration required five days, during which time the catalyst was reactivated several times by briefly stirring the reaction mixture in air. The reaction mixture was then fractionated through a small Podbielniak column (about 25 theoretical plates) to remove the large excess of acetone. When all the acetone had been removed, 54 cc. of water was added in order t o exchange the hydroxylic deuterium of the isopropyl alcohol with the hydrogen of the water. Then the distillation (through the same column) was resumed. The fraction collected was 15 g. of the azeotropic mixture of isopropyl alcohol and water. Some of this azeotrope was used directly for rate measurements; some was reequilibrated with water. The latter portion was prepared by adding 8.5 g. of the azeotrope to 100 g. of water, and then redistilling the mixture through the same Podbielniak column, The composition of the azeotrope was calculated as 90.1% deuteroisopropyl alcohol and 9.9% water from the combustion analysis of the material. (Microanalysis by Wm. Saschek, C, 53.40; H, 12.82.) Both portions of the azeotrope (that equilibrated once and that equilibrated twice) had the same rate of oxidation. The work of Anderson and MacNaughtona suggests that in the deuteration all the deuterium gas is taken up at the carbonyl group, and the resulting product should be pure
OD
CHsC-CHa. D
If this were the fact, the product after equili
-
OH bration with water should have been pure CH&-CH3. D Regrettably, however, the isopropyl alcohol which we prepared was a mixture containing only about 5570 of the desired 2-deuteroalcohol. Fortunately the qualitative (5) Knowtton and Rossini, Bur. Standards J . Research, 19, 605 (1937). (6) .4nderson and MacNaughton, THISJOUBNAL, 64, 1456 (1942): see also Carothers and Adams. ibid., 46, 1675 (1924).
F. S. WESTHEIMEBAND NICHOLAS NICOLAIDES
Vol. 71
TABLE I 2-DEUTEROPROPANOL-2
bxperimentU
Concn. CrOa, mole/l.
RATE OF OXIDATION O F 55% Concn. alcohol, Concn R‘ mole/]. mole/i
Ionic strength
k, min.-l (mole/l.)-* kri
kdkm
bib
0.40 2.04 1.88 0.3143 40 1.09 -3140 “3120 40 2.30 1.90 .3120 40 1.21 005480 3143 40 1.73 1.91 40 .907 .006520 ,03059 .314G .2046 ’10x3 .QO 2.77 1.89 IV 005591 40 1.47 D-IV .005520 .213E( 1082 * In those experiments prefixed with the letter ‘*D,”the isopropyl alcohol used contained 55% deuterium on the central carbon atom. b The symbol kD1 represents the rate constant for the isotopically impure 2-deuteropropanol-2. I D-I I1 D-I1 I11 D-I11
O.OOM80 -005520 “ 001059 ,001059
0.2072 .2139 .2061 .2139 .02960